Report No. COOT -DTD-R-92- 1
COLORADO DEPARTMENT OF
TRANSPORTATION ASPHAL T PAVEMENT WHITE PAPER
COOT ADVISORY TI:AM COLORADO DEPARTIvENT OF TRANSPORTATION 4201 East Arkansas Avenue Denver. Coloredo 90222
JANUARY 1992 Second Printing
Prepared in cooperation with the U.S Department of Transportation Federal Highway Administnation
Technical Report Documentation Page
1. Report No. Z. Government Accession No. 3. Recipient's Catalog No. CDOT-DTD-R-92-1
4. Ti tle and Subtitle 5. Report Date
Colorado Department of Transportation January, 1992 Asphalt Pavement White Paper
6. Performing Organizati on Code File No. 11.15
7. Author( s ) 8 . Performing Organizati on Rpt.No. CDOT Advisory Team CDOT-DTD-R-92-1
9.Performi ng Organization Name and Address 10. Work Unit No.(TRAIS) Colorado Department of Transportation 4201 E. Arkansas Avenue Denver, Colorado 80222 11. Cont ract or Grant No.
12. Sponsoring Agency Name and Address 13.Type of Rpt.and Peri od Covered Colorado Department of Transportation Implementation 4201 E. Arkansas Avenue Denver, Colorado 80222 14. Sponsoring Agency Code
15. suppl ementary Notes Prepared in Cooperation with the u.s. Department of Transportation Federal Highway Administration
16 . Abstract
Over the past several years, numerous changes have been incorporated into the hot bituminous pavement design and construction process. Design and construction problems encountered during the 1991 asphalt paving season as a result of these changes have been identified and corrective actions are addressed in this paper .
17. Key Words 18. Distribution Statement Gradation, VMA, Compaction, No Restrictions: This report is In-Place Voids, Segregation, available to the public through, the Lime Mixing National Information service,
Springfield, virginia 22161
19 . Security CLass if. (of thi s report) 20 . Security Cl85s i f . (of th i s page) 21 . No. of Pages 22. Pri ce Unclassified Unclassified 63
i
section
TABLE OF CONTENTS
Page
Number
Executive Sulnlnary . .. ... .... ..........•.•.. .... .. . .. . . . 1
I . Background ...................... .. .................... ..... .......................... .. ...... 3
II. Purpose ••... .. . . .. . .... .............. ................. 4
III. Major Issues
A. Mix 1. 2. J. 4. 5.
Design Gradations ............................................ .... ............ ....... ... 5 VMA ............... ..... ...... ...................... .... ... ........... 10 Compaction . .... ......... ....... . . .. ... .. . .... 10 In-Place Voids ••.........••.••..........•.•.. 12 Segregation .......•......•••.•.. ............. 12
B.. Lime Mixing ........................................................................... 13
C. Construction/Maintenance Seal Coats ••••.......... 14
D. Training Activities •....••• ............... ••..•.. 15
E. Regional Design Factors .... ......... .••.......... 16
F. Additional Laboratory Issues ... . . . ............... 17
IV. Other Flexible Pavement Activities . ...... . ........... 18
V. Staff Materials Flexible Pavement unit ' s
Position Statement .• .. ... .. ....... . .... . .. .. . . ... . ... 19
Figure
Number
LIST OF FIGURES
Title
Page
Number
1 Forbidden Zone ....... .. .. .................................................... .. .......... . 7
Improved Aggregate Gradations 2 SHRP Fine •.............. •.... •. ......... .......... .... 8 3 SHRP Coarse .... . ....... ........... ..... .... . ..•....... 8 4 Gap-Graded . . . ... .. .............. .........• •......... . . 8
11
APPENDICES
Appendix A . . ...•• CDOT Asphalt White Paper Report Members
Appendix B ......• Project Reviews
Appendix C ....... Draft Quality Assurance Review Report for 1991
Appendix D •...... Master Range Table for HBP
Appendix E ....... Modified Range Table for HBP (Improved Gradations )
Appendix F ....••• Proposed Colorado Procedure for Determining Segregation
Appendix G ....•.. Aggregate Moisture Content with Lime
Appendix H . ...... Colorado Flexible Pavement Oversight Group Task Force Members
Appendix I ....... Gyratory Compactor Test Procedure
iii
EXECUTIVE SUMMARY
Over the past several years, numerous changes have
been incorporated into the hot bituminous pavement design
and construction process. Design and construction
problems encountered during the 1991 asphalt paving season
as a result of these changes have been identified and
corrective actions are addressed in this paper . The two
most notable problems were segregation and compaction.
Both problems appeared to have increased this year
primarily because of the use of coarser, high stability
asphalt mixes with lower asphalt cement content.
The AC contents were lower during the 1991
construction season because of the new design procedure
using optimum AC content vs minimum percent AC and the use
of the Texas Gyratory compactor. Low AC content
associated with the use of a 2-1/2" samples for Texas
Gyratory designs have been identified and corrected with
the change to the ASTM 2" high sample. This change in
sample height will result in design AC contents averaging
approximately 0. 5% higher during the 1992 construction
season.
A design procedure requiring a minimum lift thickness
of 2" has been implemented to reduce compaction problems
this next paving season. In addition, a compaction test
section specification, requiring the contractor to
demonstrate his capability to achieve density, is being
developed for implementation in the 1992 paving season.
To help correct the segregation problem, a Colorado
Procedure (CP) to better define segregated material has
been drafted and is proposed for use in 1992.
1
standard HBP gradations for the upcoming paving
season will continue to be COOT Grading (C), (CX), (Fl,
and (G). SHRP Coarse, SHRP Fine and Gap-Graded mixes will
be used as designated, and wil l be used on an evaluation
basis.
Coordinated effort between CDOT, local industry and
consultants has been established to identify short and long
term strategies for improved asphalt pavement construction
and performance.
Training needs for this year should be directed towards
the issues addressed in this paper. Comprehensive training
on new specifications and procedures, as they are
implemented, need to be provided to both CDOT and
contractor ' s employees .
2
I. BACKGROUND
COLORADO DEPARTMENT OF TRANSPORTATION
ASPHALT PAVEMENT WHITE PAPER
January 1992
Early distress on Colorado ' s asphalt pavements has
prompted the Department of Transportation to make
modifications to the procedures used in the pavement mix
design and material specifications. These modifications,
having taken place over the past several years on a
statewide basis, have often resulted in a greater amount
of observed pavement distress. Many of these short
comings have been the result of the failure to coordinate
the design changes to the construction process, the lack
of communication or training within the industry and other
failure mechanisms. Each of these issues has been
compounded by the demand on a s phalt pavement performance
given heavy traffic loadings, increased tire pressures and
other environmental factors.
A need was apparent to review the department ' s
current state of the practice and set forth a strategic
plan for the short and long term.
3
II. PURPOSE
The purpose of this paper i s to:
1. identify the material problems and construction concerns encountered during 1991,
2. address potential problem area and develop recommendations for the 1992 paving season, and
3. inform Colorado Department of Transportation personnel and contractors of material and construction design changes or new procedures that will be implemented in the beginning of the 1992 construction season.
To provide input for this paper an Advisory Team was
established. A Resource Team including some overview Task
Force members reviewed and provided input on the final
report. A list of the members of each team is found in
Appendix A.
Several projects constructed in each CDOT district
during the 1991 were selected in each District for
evaluation. The district materials engineers evaluated
and prepared a written report on each. The report listed
the problem areas, how they were resolved and made
recommendations for future projects. These project
summaries of the indicated that three major problems
existed during the 1991 construction season:
1 . compaction (Districts 2, 3, 4, 5, and 6) 2. segregation (Districts 1, 2, 4, and 6) 3. low AC content (Districts 3, 4, 5, and 6)
A summary of each of the projects by District is
found in Appendix B.
4
The FHWA Oversight pilot Program was established
within the Colorado Department of Transportation (COOT)
and the Federal Highway Administration (FHWA) on July 9,
1991. The program created a Quality Assurance (QA) review
program and requires the submission of an annual report,
which includes findings and recommendations, to the QA
Management Team. See Appendix C for the draft Quality
Assurance Review Report for 1991.
III. MAJOR ISSUES
A. MIX DESIGN
1. Gradations
Beginning with the 1991 construction season problems
with existing stockpiled materials meeting revised design
criteria were encountered. These problems are associated
with changing design procedures from a minimum % AC
criteria and implementing the Texas Gyratory mix design
procedure. Because of problems associated with the
revised mix design procedures contractors were permitted
to change HBP gradations from those specified in the
project plans to modified gradings that would also meet
design criteria. These changes were allowed to help
contractors better utilize their materials and to
transition into Texas Gyratory design procedures .
5
During the 1991 construction season 13 projects
utilized CDOT improved gradations [SHRP fine (SF), SHRP
coarse (SC), and Gap-Graded (GG)]. The distribution of
types of improved designs by District is:
SF District 1
2 1 3 4 1 5 6
SC
1 1 2 1 2
GG 2
2
On these 13 projects, the results of failing
stability and Lottman test results from production samples
on mixes using the improved gradations during 1991 is as
shown:
Stability Lottman 3 of 65, (4.6%) o of 65, (0. 0%*)
* This is attributed to the use of lime.
Aggregate gradation criteria will be a major area of
evaluation during 1992. There are several theories
relative to gradation criteria. The degree of mix
aggregate density can be represented on a plot of the
aggregate distribution (a 0.45 power plot). A 0.45 power
plot of a gradation indicates how dense a mix the
gradation will produce. A straight line plot indicates a
dense mix which will not have sufficient room for both air
voids and asphalt cement. Such a mix is sensitive to AC
content and may rut or strip if AC varies from optimum.
Because of the need to "go back to the basics", the
standard gradations (Appendix D) for the 1992 paving
season will continue to be Grading (C), Grading (CX),
Grading (F) on low volume roads, and Grading (G) lower
lifts. Design criteria for Grading (C) and Grading (CX)
mixes will be approached with caution to avoid mixes that
6
produce a maximum density plot. As a minimum, contractors
will be advised to develop mixes 2-3% above or below the
maximum density line. It has been recommended by
consultants Tom Kennedy and James Scherocman to avoid the
"forbidden zone" as shown in figure 1.
100
Figure 1 80
IS eo iI • • .. II.
-. 40
20
FORBIDDEN ZONE 0
111200 ~_30 ... IIEYI IIDI
This zone is defined as the area within the
boundaries of ±4% above and below the maximum density line
between the #50 and #4 sieve. Mixes above or below this
zone will be more open and less sensitive to AC content;
however the exact criteria is not known at this time and
mixes will be evaluated during the 1992 construction
season for the purpose of establishing acceptable limits.
When developing mix designs, contractors will be advised
to be aware of the "forbidden zone" and design
accordingly.
CDOT modified the SHRP fine (figure 2) and SHRP
coarse (figure 3) gradations to avoid dense mixes by
forcing gradations above or below the "forbidden zone" .
The Gap-Graded (figure 4) gradation avoids dense mixes by
going above forbidden zone at the fine end, and then
crossing over the maximum density line.
7
IMPROVED AGGREGATE GRADATIONS
100
Figure 2 80
SHRP FINE i 80
• oC .. ~ 40
20
0 ,,",,00 "30 ... ... 3/0- 1/2" 3/0-
IIEVE llZES
100
Figure 3 80
SHRP COARSE i 60
• oC .. ~ 40
20
0 ,,",,00 .30 •• ..... 31.- 1/2" 3/0'
lEVI SIZES
100
Figure 4 80
GAP-GRADED I 80 • ~ .. ~ 40
20
0 00200 .30 ... ... 310' 1/2· 3/0'
IIEVE llZES
a
These gradations were modified from those used in
1991 based on construction experience. The modifications
addressed workability problems resulting from the
coarseness of the SHRP and Gap-Graded gradations. The
SHRP and Gap-Graded gradations will continued to be used
experimentally on a project by p roject basis (See Appendix E) .
Evaluation of these improved gradation mixes will
continue during 1992. The upper limit of SHRP fines mixes
has been established at the upper limit of the Grading
(C). Several projects will be proposed to evaluate the
feasibility of extending the upper limit. It is
anticipated that both SHRP fine and Gap-Graded will be
specified this season, however SHRP coarse designs will be
evaluated on a limited basis. Gradation limits and
problems with segregation will continue to be evaluated
and fined tuned before more extensive use of the SHRP
coarse is recommended. As these "experimental" designs
are used, on a limited basis, a demonstration or open
house will be organized to illustrate the design and
construction experiences. Follow-up testing will also be
implemented
When evaluation sections are specified it is
recommended that they be of significant quantity (min 20 00
tons) to allow for crushed materials to be manufactured
within specification requirements, plant operation to be
adjusted to produce specified materials, laydown and
placement operations to be stabilized to assure that
materials to be evaluated are i n fact on the project and
other variables are elimi nated.
Reports summarizing significant findings are
recommended to be provided for state wide use when
experimental gradations are used .
A cooperative effort between Staff Materials, Staff
Construction and field construction will be needed to
provide this information.
9
2. VMA
Beginning this season COOT will compute VMA using the
bulk specific gravity of the aggregates. This will result
in lower, yet more accurate, computed VMA's. VMA's using
bulk specific gravity will be shown on test reports for
information.
VMA is affected by computation method, gradation, and
compaction method. All of these have recently changed
making it unclear what minimum criteria is appropriate.
During 1992 VMA will be reported for information only and
not a specification criteria for mix design approval. VMA
will be examined at the end of the 1992 paving season to
determine an appropriate design criteria.
3 . Compaction
During 1991, many projects experienced difficulties
obtaining density. This was a state wide problem and was
not limited to anyone gradation.
Over the past several years numerous changes were
incorporated into the hot bituminous pavement design
process. These changes were made with the purpose of
increasing the long term performance of the pavements.
Compaction is the single most important factor that
affects the ultimate performance of the pavement.
Achieving adequate compaction increases pavement
performance by decreasing rutting, reducing damage due to
moisture, and increasing the stability of the mix.
However, as a result of these changes, the newer mixes
have become more difficult to densify. Changes made in
1991 affecting compaction include:
Aggregate Improvements -- The limit on the use of
natural fines was reduced while the percentage of
fractured faces was increased. Angular particles offer
10
more resistance to densification than rounded particles.
As the amount of crushed materials increased in the mix,
the compactive effort needed to obtain densities was
increased.
Gradation of mixes also was modified. Standard
mixes now require more intermediate sieves , in effect
controlling the percentage of fines in the mix. Improved
mixes such as the SHRP fine, SHRP coarse and the Gap
Graded mixes were introduced in order to move away from
the traditional easier to compact dense graded mixes.
More compactive effort was required to compact the new
harsher mixes.
Asphalt Cement -- The change to grade and amount of
asphalt cement used in the mix also affected the ability
to densify the mix. Changing from the minimum asphalt
content to the concept of mix designs based on optimum
percentage of AC, and using the Texas Gyratory for
designing mixes, lowered the typical asphalt content in
mixes from the past. The asphalt cement content in a mix
influences compaction, and mixes with lower asphalt
content tend to be stiff and require additional compactive
effort. In the past, typical designs were based on AC-I0
graded asphalt. To reduce the potential of rutting in the
pavement, stiffer asphalts, i.e. an AC-20, are typically
specified. Again, the stiffer the mix, the more
compactive effort was needed to achieve density.
Compaction is a critical item because of the need to
assure compliance, a compaction test section specification
is being developed for implementation in the 1992 paving
season. This specification will require the contractor to
demonstrate his ability to obtain density on the first 500
tons that is placed on a project.
11
compaction must be accomplished before the mat is
allowed to cool. Those factors affecting the cooling rate
of the mat include:
Layer thickness Temperature of mix when placed Ambient temperature Temperature of base Wind conditions
Layer thickness is probable the single most important
variable in the cooling rate of an asphalt mat, especially
for thin lifts. It has become very difficult to obtain
specification density on thin lifts. This is especially
true in cool weather because of the rapid loss in
temperature in the mix and the inability of the compaction
equipment to densify the mix before it cools below 185 of.
As the thickness of the layer being placed increases, the
time available for compaction also increases. Because of
problems with losing temperature on thin lifts resulting
in compaction difficulties, a design procedure requiring a
minimum 2" lift thickness has been implemented .
4. In-Place Voids
It is also recommended that during the 1992 paving
season that each District Materials Engineer select
projects for the purpose of taking cores to evaluate in
place voids.
5 . Segregation
Another major problem encountered during the 1991
construction season was segregation. Because of the
coarseness of the mix and the lower asphalt content of the
mixes used, segregation was more evident than in the past.
with segregation being a major concern emphasis wil l
be placed on reducing segregation on all projects. A
Colorado Procedure (CP) for better defining segregated
12
material has been drafted and proposed for use in 1992
(See Appendix F). This CP is currently based on compacted
material and was developed during the 1991 paving season
on various COOT projects; however, during the 1992 season
this procedure will be evaluated to establish criteria to
be used on uncompacted material.
There are various causes of segregation yet many are
related to inappropriate stockpiling, improper mixing in
the drum dryer, surge bin and storage silo separation,
improper truck loading techniques and paver operations.
Training for both COOT and contractor employees in
recognizing and correcting segregation is recommended.
B. LIME MIXING
The specifications for 1991 required the addition of
a minimum 1% lime to the aggregates which was to be
thoroughly mixed by an approved pugmill. Several
contractors were not equipped at the beginning of the 1991
paving season and a one time exception which allowed to
use belt mixers when approved. This exception was for the
1991 paving season only. All lime mixing operations
beginning with the 1992 construction season will be in
accordance with The 1991 Standard Specifications for Road
and Bridge Construction section 401.14, Preparation of
Aggregate.
401.14 Preparation of Aggregates. Heating and drying of the aggregates shall be accomplished without damaging the aggregate. When hydrated lime is used it shall be added to the aggregate in accordance with one of the following methods: (a) Lime Slurry Added to Aggregate. The
hydrated lime shall be added to the aggregate in the form of a slurry and then thoroughly mixed in an approved pugmill. The slurry shall contain a minimum of 70 percent water by weight.
13
(b) Dry Lime Added to wet Aggregate. The dry hydrated lime shall be added to wet aggregate ( a minimum of three percent above saturated surface dry) and then thoroughly mixed in an approved pugmill.
The lime-aggregate mixture may be fed directly into the hot plant after mixing or it may be stockpiled for not more than 90 days before introduction into the plant for mixing with the bituminous material. The hydrated lime may be added to different sized aggregates and stockpiled, by adding 75 percent of the lime to the aggregate passing the No. 4 sieve and 25 percent to the aggregate retained on the No. 4 sieve.
Adequate moisture on the aggregates prior to the
addition of lime was a concern during the 1991 paving
season. When dry lime is added to wet aggregate, the
specification require the moisture of the aggregate to be
a minimum of 3% above saturated surface dry (SSD). A
draft specification revision of section 401.14 (b) is
proposed establishing moisture determination criteria,
sampling frequency, with price reduction factor (F) is
recommended and found in Appendix G.
Future items relative to lime mixing that will be
analyzed include: specification requirements for
measuring moisture of plant produced material, and
provisions for weighing the lime being added to the
aggregate.
C. CONSTRUCTION/MAINTENANCE SEAL COATS
Districts should inspect projects each Fall and
determine if any preventative maintenance in the form of
fog sealing, etc. is required. The use of rejuvenating
agents should be limited and is not recommended for use on
segregated pavements.
14
D. TRAINING ACTIVITIES
The consensus of the Advisory Team was that training
for both department and contractor personnel is a high
priority item.
The District Construction and Materials Engineers
should include the white paper topics in their winter
training sessions. Both project engineers and project
testers need to be included in winter training activities
relative to the white paper issues.
Changes to design procedures and CDOT expectations
need to be disseminated to all contractors and suppliers .
The contents of this report should be emphasized. Internal
training within the contractor community, geared to field
operation personnel needs to be reinforced. Both CDOT and
contractor personnel should be trained in identifying
causes and solutions associated with equipment and mat
problems. Such problems areas in addition to segregation
should include:
tearing non-uniform texture screed marks screed responsiveness longitudinal and transverse j oint problems checking shoving bleeding and fat spots
A pre-bid conference when maj or specifications or
procedures are implemented, is recommended. Pre-paving
conferences need to be comprehensive and details of new
specifications and procedures reviewed in detail for the
benefit of both state and contractor personnel.
15
E. REGIONAL DESIGN FACTORS
It is proposed to develop " regional design" criteria
based on performance needs. criteria for mix designs
would be based on performance expectation, i.e. high
performance design criteria specified for high volume,
heavy traffic areas - low volume areas would not require
the same criteria and would benefit from a different mix
design.
The basis of providing an alternative method would be
to allow for the selection of a mix to satisfy both the
pavement design and system
The guidelines for using a
needs for a specific location.
"regional
based on good engineering judgement
design" would be
and the proposed
criteria for specifying a "regional design" would be:
1. Traffic considerations - locations with relatively low volume «5,000 ADT) or locations that may have h igh ADT's but low or restricted truck traffic.
2. High altitude locations- an elevation of 8,000 ft or greater.
3. Resurfacing projects - single lift overlays on structural adequate but with oxidized, cracked pavement. These pavements may be best served with mixes with higher AC contents and a reduced compactive effort.
Because of the numerous combinations of design
factors that are encountered throughout the State, it is
important to provide the best design for the job. All
design factors are to be taken into consideration when
evaluating the need for a "regional design"; this
alternative method would not be suggested for high volume
facilities.
16
F. ADDITIONAL LABORATORY ISSUES
There are numerous issues relating to asphalt
pavement design, performance and constructibility that
will continued to be looked into. COOT, along with FWHA,
will be obtaining European testing equipment to develop
mix designs. This equipment will be used to determine
performance related design criteria.
Aggregate improvement criteria will continue to be investigated. Items that are of concern include:
1. limiting the amount of natural fines on high volume roads
2. angularity of particles 3. cleanliness of aggregates in terms of sand
equivalency.
The quality of asphalt cements is a concern and
additional criteria such as penetration testing (before
and after aging) and ring and ball (before and after
aging) are being considered.
Rubberized mixes will continue to be used; however ,
this will be on a limited basis and districts will
determine when to specify rubberized HBP. The use of
rubberized plant mixed seal coats are to be limited and
only placed on existing pavement or milled surfaces that
do not show signs of stripping or severe raveling.
Evaluation of polymers, as defined by AASHTO Task
Force 31, will continue during the 1992 paving season.
In the past experimental features have been
implemented without significant performance evaluation and
has lead to significant design changes. It is felt that
experimental features should be considered in the form of
demonstration projects only and not implemented on a state
wide basis until sUbstantial performance results have been
17
achieved. Items new that may b e considered in the future
would include: warranty projects, split mastic asphalt
designs (SMA), QA/QC projects with incentive and
disincentives. Incentives and disincentives based on
gradation, % AC, compaction, and asphalt smoothness will
be developed for use in 1992.
IV. OTHER FLEXIBLE PAVEMENT ACTIVITIES
The Colorado Flexible Pavement Oversight Group has been formed to address asphalt pavement issues. This group is organized into the following categories:
1. Pavement Management 2. Pavement Design and Rehabilitation 3. Material Selection Specifications 4. Mix Design Systems 5. Training 6. New Materials Technologies 7. Constructibility Factor 8. QA/QC 9. Awards
A list of the group members can be found in Appendix H.
18
V. STAFF MATERIALS FLEXIBLE PAVEMENT UNIT'S POSITION STATEMENT
Low Asphalt Cement Content
Problem: Use of the gyratory compactor has resulted in
lower optimum asphalt cement contents than were obtained
in the past using the kneader compactor. This has caused
field compaction difficulties (below) and has raised
concerns about durability. Solution: The gyratory
compactor test procedure is being modified (Appendix I) by
reducing specimen height. This will result in higher
optimum asphalt cement content. In addition we are
considering using even higher asphalt cement contents for
pavements with low traffic, high altitude and/or thin
lifts. We are in the process of hiring a consultant to
examine our mix design process and make recommendations on
asphalt cement content, gradations, etc.
Compaction Difficulties
Problem: Low asphalt cement contents has resulted in
compaction difficulties. Contractors have difficulty
obtaining the specified minimum density of 92% of maximum.
Thin li fts and/or high altitudes aggravates the problem.
Solution : This problem will be reduced by the higher
asphalt cement contents obtained by modification of the
gyratory procedure. Training of CDOT and Contractor
personnel will familiarize them with steps to take to
overcome compaction difficulties (available training
listed below). Specifications are being developed that
require the Contractor to demonstrate the ability to
obtain compaction on a test strip before paving is
allowed.
19
Segregation
Problem: Segregation has been a serious problem for CDOT
pavements for many years. The use of coarser gradations
and lower asphalt cement contents has aggravated the
problem. Segregation is the result of poor construction
techniques. Coarse segregated areas tend to ravel
prematurely.
Solution: CDOT and Contractor personnel need to be trained
on the causes of segregation and techniques for prevention.
Training which will address segregation is listed below.
Lime Mixing
Problem: Hydrated lime is required in most CDOT mixes to
prevent stripping. It is critical that the proper amount
of lime and water be added to the aggregate and that it be
thoroughly mixed in. Some Contractors have been reluctant
to install an adequate pugmill for mixing in the lime. On
many projects it has been noted that too little moisture
is being added and/or it is not being added uniformly.
Solution: Most Contractors now have adequate pugmills for
mixing the lime with the aggregate. We must now focus on
adding sufficient moisture to the aggregate in a uniform
manner. This will require new procedures for Staff
Materials and project testers. Staff Materials must
provide the saturated surface dry (SSD) moisture content
to the project tester. On the project the moisture content
after moisture is added must be determined. If moisture
content is less than the required 3% over SSD the
Contractor must correct the problem. Project personnel
need to be trained on all aspects of lime addition,
including moisture content. The uniformity and amount of
lime added is another important issue that should be
addressed.
20
Asphalt Mix Testing in District Labs
Problem: District labs are being equipped this winter to
conduct Hveem stability and Lottman tests on asphalt mix.
It is intended that most testing of project produced mix
be conducted in the district. It is critical that the
results obtained by the district be accurate and credible.
Solution: The following steps will be taken to assure the
quality and credibility of the district testing of asphalt
mixes.
1. District materials testers are being trained in Staff Materials on the Hveem and Lottman tests.
2. After all equipment is installed and operating, each district lab will be inspected by a team from Staff Materials to assure that equipment is properly set up and procedures and being followed.
3 . Round-robin testing will be conducted to compare results obtained by each district and Staff Materials. There will be a follow-up on any sUbstantial discrepancies.
4 . At the start of next season, production samples will be tested both in the district and in Staff Materials. This parallel testing will continue until confidence in the results is established.
Lottman Credibility
Problem: The Lottman test is the standard CDOT test for
moisture susceptibility of asphalt mixes. Contractors
have repeatedly attacked this test, claiming that it is
not repeatable.
solution: A research study is u nderway to determine the
repeatability of the Lottman test.
21
critical Asphalt Mix Training
COOT Winter Training for Project Personnel This training should address field compaction, segregation, and lime mixing.
certification Course for Bituminous Materials Technicians This course is sponsored by CAPA. The level II course will cover compaction measurement. It would be desirable if this course covered segregation and compaction difficulties.
Technical Training Program by James Scherocman / Tom Kennedy This 4 1/2 day course was sponsored by CAPA. Topics included placement and compaction of asphalt mixes. Segregation and compaction problems were covered.
22
APPENDIX A
COOT ASPHALT WHITE PAPER REPORT MEMBERS
Denis Darmelly, Chairman staff Materials Tim Aschenbrener, staff Materials lewis Garton, District 4 Constnlction Darma Harnlelink, Research Dick Hines, staff Materials steve Horton, staff Design sid MotdJan, District 6 Materials GerJ:y Peterson, District 1 Materials Hal Toland, staff Constnlction Ken Wood, District 4 Materials
VUk Aguirre, Aguirre Engineers Inc. Skip Bettis, Bituminous Roadways of Colorado, Inc. Bob Bisgard, Asphalt Paving Co. D:Jyt Bolling, FHWA Bud Brakey, Staff Materials Tony Collins, Kiewit Western Co. Rick De Ia castro, CAPA Joe Murry Ira Paulin, carder, Inc. Bcb Rask, AsIiJalt Institute LOug Shaffer, Director of Maintenance and Operation Mark 8wanlUIrl, FHWA Rick Yowell, District 1 Constnlction
A-I
APPENDIX B
PROJECT REVIEWS
PROJECT REVIEWS
DISTRICT ONE
PROJECT IR(CX) 070-4(157) (Cedar Point west - westbound): The plans called for HBP Gr. C rubberized, but that was changed to a rubberized gap graded mixture by CMO. A minor problem was the rubberized mix being picked-up by the pneumatic roller. This was solved by the use of only steel rollers. Everything else went well on the project except for a segregation problem.
The segregation occurred at the end of the dump trucks. After a meeting with the project personnel, district materials personnel and the contractor's representative, the following procedures were adopted to correct the problem: The windrows would be overlapped, the hopper would never be allowed to get below half full before stopping the lay down machine, and the material in the hopper at the end of the day would be wasted. This solved the majority of the segregation problems.
Density tests were performed on and adjacent to areas that looked segregated. The segregated sections were from 3% to 14% less dense than the adjacent sections. Two extremely bad areas were removed and replaced at the end of construction. Obviously segregated areas directly behind the lay-down machine were removed and replaced before compaction.
Sample specifications for using this method to test for segregation are included in Appendix E.
PROJECT FRI(CX)CY 070-5(59) (East of Limon - milling): Grading G inlay in various locations, followed by a fog seal over the entire project. Conveyor type trailers have been used to fill the laydown machine in order to reduce segregation. Everything seems OK with the project except for the Lottman values and some stripping.
Lottman values have not met the specified minimum of 80. It was thought that this was attributed to insufficient moisture (spec 3% above SSD) on the aggregate before the introduction of the lime. The contractor increased the amount of water sprayed on the aggregates, but they were still unable to get passing Lottmans. They replaced some of the natural fines with crusher fines and were able to get passing Lottmans.
Stripping has occurred at five locations, each about four foot square. As a short term solution, the contractor has placed a tack coat and compacted some fines at each location. Each area will eventually be ,removed and replaced.
B-1
DISTRICT TWO
PROJECT CXFR 17-0287-08 (12.5 miles south of Lamar - south): This project was constructed in September and October of 1990 . It consisted of placing an HBP Gr. CX leveling course followed by Petromat and 4-1/2" to 6" of HBP Gr. C in three lifts. Major distress was noticed in the roadway in July of 1991. Problems on and after the project included: segregation, inadequate compaction (high air voids), stripping, bleeding and rutting.
Assurance tests taken after the project was completed indicated compaction was only 89% to 91% as opposed to the 92% to 93% measured by quality control testing based upon the RICE method. District personnel indicated this was not uncommon.
Project personnel waged a continuous struggle to mitigate the segregation problem, but were not successful. The segregation was caused by the contractor's stockpiling technique and plant operations.
At the end of the project, an asphalt rejuvenating agent (ARA) was sprayed over the entire surface to fill the excess voids since segregation was so severe. This seems to have severely aggravated the problem. The application of the ARA penetrated the air voids and softened the asphalt. The soft asphalt was very susceptible to stripping. Moisture penetration with high heat and traffic caused stripping to occur. The stripped asphalt bled to the surface, weakened the section, and then rutted.
The stripping was occurring predominantly in the top lift. Moisture could be seen seeping from the surface several days after a rain shower. Bleeding occurred in the wheel paths throughout the project.
PROJECT CX 04-0083-41 (Jct SH 83 Spur - south); Samples run at 4'.4% AC at 2-1/2" height passed the Hveem but failed the Lottman . The mix was re-run with 2" high samples and a new optimum AC of 5.0% was obtained and the Lottman's passed. The rice value was adjusted based on numerous tests on the project produced material. Before the AC content was increased, a previous experimental SHRP Fine mix was used with the same aggregate and an AC content of 4.7%. It was difficult to get density with this AC content. passing densities were obtained, but there was evidence of aggregate breakage. This problem was eliminated with the new higher AC content.
The QC/QA specification seemed to help on this project. The contractor's own quality control person caught an error in the AC content and corrected it before the required tonnage for the first random field acceptance test. In addition, the contractor had a nuclear density gauge on the project at all times. They were thus able to develop their own rolling patterns and check it themselves, this freed up the project tester. The success of the
B-2
QC/QA was attributed to the experience and proficiency of the contractor's QC person.
Only one acceptance test out of 29 failed density.
There were no failures on AC content acceptance tests at both the original and revised AC contents. One Central Lab check test failed, but the retained split passed in the District Lab.
There were no failing gradation tests and consequently the frequency of testing was reduced after the first ten tests .
Dry lime was mixed in a 10 ft. pugmill with wet aggregate and stockpiled. This provided two benefits; consistently high lottman values, and the ability to check if the lime was actually added (it could clearly be seen in the stockpile) .
DISTRICT THREE
PROJECT CY 59-0125-19 (SH 125 and SH 127 Wyoming line south): The design mix was marginal but was approved. Construction began about July 15, 1991.
The major problem with this project was density. A minor problem was some gradation variation.
The quality control subcontractor had problems getting their nuclear testing equipment by the time paving started. This created some problems with the calibration for asphalt content tests. In addition, the QC subcontractor, though knowledgeable about testing and inspecting, was not familiar with CDOT methods and documentation procedures.
AC contents and gradations were erratic the first few days. Some gradation problems occurred because aggregate was taken directly froin the crusher to the hot plant rather than stockpiling.
Densities at first averaged 87%. One of the contractor's rollers was broken down during part of this time. Different roller patterns were tried and the densities were increased to 91%. A thicker lift was placed on the theory that the previous lift may have been too thin to get valid results, but this did not help.
On August 15, the AC was. increased from 4.3% to 5.5%. The density problem was solved, but the increased AC may make the stability of the mix lower.
PROJECT CC-CX-21-0050-15 (Cimarron): The mix was designed with the Texas Gyratory procedure, using highly absorptive aggregate. Paving began on September 23, 1991. The major problem encountered on this project was inadequate compaction. A secondary problem was high moisture content.
B-3
The contractor was shut down after three days because of densities around 86%.
CDOT observations of the roller operation: 1 . The rollers stopped when the laydown machine stopped. 2. The rollers were going too fast. 3. No real attempt to establish a consistent rolling pattern.
Contractor's proposed corrective actions: 1. Increase AC to 6.2% from 5.9% 2. Increase hot plant temperature and dry the moisture out of the mix (CDOT suggestion) 3. Slow down the breakdown roller (CDOT suggestion)
The contractor was allowed these corrective actions. properly, but was fixed as achieved.
to proceed after a test patch with The vibrating screed was not working well. Densities of 93%+ were
On the last patch the AC was again reduced to 5.9% and 93% density was still achieved.
In some, if not all cases, it may be necessary for the contractor to have two breakdown rollers in order to keep production rates up.
DISTRICT FOUR
PROJECT FRI(CX) 025-3(114) (Owl canyon north): At the c.ontractor's request, this mix was changed from a grading C to an SC (SHRP coarse). stabilities have been 40 plus and Lottman's have been 95 to 100. This project is an overlay of a PCCP pavement. This project was started late in the 1991 paving season and will be completed next spring. The lay down of this mix has gone fairly weil. There have been two problems; compaction and segregation.
Densities are low, but the contractor has been able to meet specifications. with the rock to rock contact in the thin (1-1/2") lift, the vibratory roller may actually be reducing compaction after a point. Rubber tire rollers have been SUbstituted now for breakdown with some success. The lift should be increased to 2".
Going from a 2-1/2" sample height to a 2" sample height has increased the AC content from 4.3% to 4.4%. This increase in AC content also helps with compaction.
Cooler fall temperatures have also made it more difficult to obtain compaction.
Segregation has occurred, and with it, some ravelling (but not stripping) in the surface of the mat. This ravelling is also
B-4
associated with the low AC content. switching to a rubber tired roller for breakdown may have reduced the ravelling by kneading and turning the coarser particles to optimize their fit at the surface. The mix must not be allowed to cool off too much because coarser particles separate and roll when cool.
The project was partially sealed with CSS-lh to help prevent further ravelling of the surface.
contractors need to learn how to handle these types of mixes better. They may need to buy more rollers or upgrade the equipment they have, keep laydown machines adjusted, understand roller tire pressures and what happens when they heat up and/or cool down, learn how to handle material from the hopper to the storage silo to loading the trucks to depositing the material on the roadway woul d go a long way t owards a better product.
PROJECT FR(CX) 085-3(13) (Lone Tree Creek to Little o wl Creek): This mix was a grading C with an optimum AC content of 4.8 %, designed by the Texas Gyratory method. The pavement was placed in May and June of 1991. The major problems on this project were segregation and insufficient densities. Additional related problems were a non-uniform mix, non-uniform addition of lime, and sometimes excess moisture.
The contractor was unable to achieve density during the first three days. After that he was able most of the time, but not all of the time. No consistent increase was achieved by simply increasing the AC. Changing the rolling pattern did not seem to help much, except for the use of a rubber tired roller for breakdown sometimes. When he was able to reduce segregation, that helped increase the density. The non-uniform mix was difficult to compact. In addition, the contractor was not able to take advantage of what uniformly added lime does for the compactive effort. The excess moisture made the mix tender at first, then cooled the material so that it was impossible to achieve density.
In the last days of the project, a previously developed SHRP Coarse mix was substituted, and with the contractor's experience during the beginning of this project, he was able to produce a good quality pavement.
In general, the contractor's inexperience with these unforgiv ing mixes, and his inconsistent production were the cause of the segregation and density problems.
The surface has been treated with .05 gal/sy of CSS-lh to st~bilize the open and segregated surface. Reclamite was used briefly, but was too slick~
To address the compaction problems, a first day evaluation of t he placement and rolling operations is now performed using a
B-5
prepared checklist, which provides some guidance for the project engineer and contractor.
other recommendations: Increase AC, pay extra for the required compaction, more and/or heavier rollers, rubber tired rollers.
DISTRICT FIVE
PROJECT CY 32-0666-02 (South of Cortez): The project consisted of cold recycling the existing pavement 4" deep with a 4-1/4" HBP overlay, place with a 1-1/2" bottom mat and a 2-3/4" top mat. The grading was changed from C to SRRP Coarse at the contractors request. The material actually placed was somewhat finer than an actual SHRP Coarse mix. The design AC was 4.2%.
The major problem on this project was compaction. Segregation was a problem early, but that was remedied.
The contractor tried various rolling patterns but was still unable to get compaction. After meeting with COOT, the contractor increased the AC content-by .5%, increased the depth of the bottom mat from 1-1/2" to 2-1/4", and increased the mix temperature. This cured the compaction problems, but not until the bottom mat was completed.
There was some concern that the cold recycle was not sufficiently strong to allow compaction of material place on top of it. However, cores t aken in the bottom mat showed broken aggregate in the new paving material and it was concluded that that wasn't the problem.
The District does not recommend continuing with the extremely coarse aggregate mixes and also opposes low asphalt content.
DISTRICT SIX
PROJECT CX 01-0025-58 (1-25. Colorado to 6th): This project consists of planing and 2" of RBP with a polymer additive. Prior to construction, the grading CX was changed to SHRP Coarse with no lime.
Four different mixes were placed on this project with substitutions of aggregate and AC type, each with its own 1st rep and 10k series.
Construction started out well. After the fourth night of paving, compaction problems developed. A roller pattern study determined that two passes of the breakdown roller and three passes of the intermediate roller (both vibratory) were optimal . This pattern was continued for the rest of the project and no more compaction problems occurred.
B-6
Longitudinal joint problems occurred. The contractor used a 10" fabricated shoe to taper the lift from 2" to 0". The coarse aggregate needed to be swept up in the adjacent lane. When the adjacent lane was paved, segregation occurred at the joint because of the thinness of the lift.
Some suggestions from the RE were to place the coarse mix projects early in the season to allow traffic to heal the surface during hot weather, and to place a +/- 1% tolerance on the -#200 sieve for coarse mixes. since film thickness could be significantly affected at the lower optimum AC contents used in the coarse mixes.
B-7
APPENDIX C
DRAFT QUALITY ASSURANCE REVIEW REPORT FOR 1991
DRAFT QUALITY ASSURANCE REVIEW REPORT FOR
PROOWl REVIEWS - SPECIAL ~IS AREAS
The program established joint FHWA/coor teams to make QA project reviews. The enq:Jhasis areas chosen for program review in 1991 were:
1. Asphalt Pavement 2. Concrete Pavement 3. Work Zone Traffic Control
EMlHASIS AREA # 1 - AS~T PAVEMENT
PROJECTS RMEWED
Asphalt Pavement QA Reviews were conducted during the period from June to october 1991 and the following projec:ts were inspected:
1. IR(CX) 70-4(157) 5. CX 99-6000-57 2. CX-OI-0025-58 6. F.RI - 70-5(56) 3. FCU(CX) 093-1(12) 7. FR(CX) 014-2(24) 4. I(CX) 70-2(141) 8. F.RI(CX) 25-3(114)
TEAM MEM3ERS
The members of the 1991 QA Review Team for Asphalt Pavement were:
1. Mark 8wanlund - FHWA - Team leader 2. Joe seitz - coor - staff Construction 3. Steve Horton - coor - Staff Design 4. Dick Hines - coor - Staff Materials
The appropriate District Materials Engineer, District Construction Engineer, Resident Engineer and Project Engineer were included as members of the revieiv team for each individual project.
FINDlMiS MIl REa»1ENDATIOOS
I. compaction:
A. Findings:
1. The majority of the projects reviewed experienced problems obtain:in::J the required density.
C-l
" .,' . ~.,
rbJ L ~c./'~~:.i~ ~ E1'4PHASIS AREA # 1 - ASPHALT PAVEMENT
2 . '!he cror changed their method of designing asphalt pavement mixes this year. '!he new procedure uses a Texas Gyratory compactor. The previous procedure used a Kneading CoItpactor. '!his change in design procedure resulted in lower asphalt cement contents and the new mixes required an increased compactive effort to obtain the required densities.
3. '!he new asphalt mixes recommended by the strategic Highway Research Program (SHRP) (SHRP Fine, SHRP Coarse and SHRP Gap Graded) were used on several of the projects that were reviewed. 'Ihese new mixes also require more corrpactive effort than the traditional mixes used by cror. (Grading C, ex, etc.)
B. Recommendations:
1. '!he corrpaction test section specification, being proposed by CDOT, should be implemented statewide for the 1992 construction season. This specification requires that contractors demonstrate the ability to obtain the specified density on the first 500 tons of asphalt pavement placed on each project.
2. '!he mininunn lift thickness of two inches, being propcsed by CDOT, should be implemented statewide for the 1992 construction season. '!his additional thickness will help maintain the temperature of the asphalt mat and allow more time to obtain corrpaction. '!his is especially critical in the following areas:
a. Asphalt pavement being placed at night.
b. Asphalt pavement being placed early in the spring or late in the fall.
3 . When a contractor experiences difficulty obtaining density , the following procedures should be tried before considering a change in the asphalt mix design or density requirements:
a. Rollers should be operated as close to the asphalt paver as possible.
b. Rubber tired rollers should be used to breakdown roll.
c. Larger rollers should be used.
d. '!he ~ture of the asphalt mix at delivery should be raised.
C-2
EMPHASIS AREA # 1 - ASPHALT PAVEMENT
II. Segregation:
A. Findings:
1. Segregation was a moderate to severe problem on most projects.
2. Factors =tributing to segregation:
a. Material handing techniques.
b. Asphalt paver operation.
c. Coarse graded asphalt mixes.
d. IJJW asphalt cement content.
e. Thin lifts.
3 • The following are same procedures that were observed to reduce segregation:
a. Use of flow-boy hauling units.
b. Using a windrow pickup machine.
c. Dumping the wings on the hopper of· the asphalt paver only occasionally.
d. Keeping the hopper on the asphalt paver at least half full at all times.
e. Proper material handling.
B. Recommendations:
1. The specification to determine segregation, being developed by CDOT, should be implemented statewide for the 1992 construction season. This specifications utilizes the nuclear density gauge to determine segregated areas :immediately behind the asphalt paver. It is intended that the segregated areas will be removed and replaced while the material is still hot.
C-3
EMPHASIS AREA # 1 - ASPHALT PAVEMENT
2. Extensive training, in the methods and pr=edures to minimize segregation, should. be provided to all cror construction personnel and the contractor's employees before the start of the 1992 construction season. (The joint FHWAjcror 2 day training session, "Hot Mix Asphalt Paving", that will be offered to each cror construction employee and contractor personnel this winter will provide this training.)
3 . When segregation occurs on a project the following should be carefully reviewed in an attempt to minimize the segregation:
a. Material handling techniques.
b. Asphalt paver operation.
III. Contract Modification Orders (CMOs):
A. Finding:
1. On several of the project reviewed, the specified asphalt mix gradings had been changed by CMO to other gradings. (SHRP Fine, SHRP Coarse, or Gap Graded)
B. Recommendations
1. Specified asphalt mix gradings should not be changed by CMO. The asphalt mix gradings that were specified should be constructed as advertised and bid.
2. If it is desirable to use other asphalt mix gradings, they should be included in the preconstruction process and advertised and bid.
IV. IDngitudinal Joints:
A. Finding:
1. Excessive raking of the longitudinal joint on several projects resulted in an open surface and poorly constructed joints.
C-4
EWliASIS AREA # 1 - ASPHALT PAVEMENT
B. ~ations:
1. Contractor arrl C!XJI' constnlction personnel should receive training in the proper constnlction of longitudinal joints before the start of the 1992 constnlction season. ('Ibe joint FHWAjC!XJI' training session, "Hot Mix Asphalt Paving" which will be offered to each C!XJI' construction employee and contractor's personnel this winter will provide this training.)
2. IDngitudinal joints should be constnlcted as follows:
a. 'Ihe screed of the asr;halt paver should overlap, onto the previously placed nat, approximately two inches.
b. '!he depth of the new asphalt naterial in the overlapped area should be one quarter of an inch deep for each inch of thickness being placed.
c. Very little , if any, raking of the joint should be done.
V . Independent Assurance Test Results:
A. Finding:
1. '!he Independent assurance test results were not available on most of the projects at the time of the review.
B. ~tion:
1. New procedures need to be :iItplernented to ensure more timely reporting of these test results. ('!he District Materials Labs are purchasing equipment to perform these tests. Operation of this new equipment by the District labs should provide a quicker response.)
VI. Quality of Contract Documents:
A. Finding:
Several project personnel felt that the contract documents were not adequate. '!hey stated that they did not feel they had enough time to properly review the contract documents before the project went to bid.
B. Recommendation:
1. '!he preconstnJ.ction process should provide JOC)re time for the constnlction personnel to review and comment.
C-5
EMPHASIS AREA # 1 - ASPHALT PAIJBv100
VII. Including Baghouse Fines in Asphalt Pavement Mixes:
A. Findings:
1. Aggregate gradation acceptance test sampling for all projects was done off the cold feed belt.
2. The Contractor was reintroducing "baghouse fines" into the dryer drum on some proj ects.
3. There was no consideration given to this material when the gradation test were run.
B. Recommendations:
1. The linpact of the introduction of baghouse fines should be carefully studied during the 1992 construction season. Both the amount and the gradation of this material need to be investigated.
2 . A correlation should be made from the above research for use in future years.
C-6
APPENDIX D
MASTER RANGE TABLE FOR HBP
MASTER RANGE TABLE FOR KBP
TABLE 703-3
Master Range Table For Hot Bituminous Pavement
sieve Size
1-1/2" 1" 3/4" 1/2" 3/8" #4 #8 #30 #200
Percent by Weight Passing Square
Grading Grading Grading G e
100
63-85 100 46-78 70-95
60-88 22-54 44-72 13-43 30-58
4-22 12-34 1-8 3-9
Passing No. 8 and larger sieves Passing No. 30 sieve Passing No. 200 sieve
D- 1
ex
100 74-95 50-78 32-60 12-34
3-9
Mesh Sieves
Grading
±8 % ±6% ±2 %
F
100
45-85
7-13
APPENDIX E
MODIFIED RANGE TABLE FOR HBP (IMPROVED GRADATIONS)
sieve Desig-nation
3/4" 1/2" 3/8"
#4 #8 #30 '200
MODIFIED MASTER RANGE TABLE FOR HBP (IMPROVED GRADATIONS)
DRAFT
TABLE 703-3 MASTER RANGE TABLE AND TOLERANCE
TABLE FOR HOT BITUMINOUS PAVEMENT
Percent by Weight Passing sieve
Grading Grading Grading SF SC GG
100 100 100 76-95 70-90 70-90 72-88 58-76 58-76 54-72 38-56 40-60 40-58 24-38 36-54 18-34 8-20 18-34
3-9 3-9 3-9
E-l
1-16-92
Tolerance
±6 ±5 ±5 ±4 ±4
±2.0
APPENDIX F
PROPOSED COLORADO PROCEDURE FOR DETERMINING SEGREGATION
PROPOSED COLORADO PROCEDURE FOR DETERMINING SEGREGATION
DRAFT
COLORADO PROCEDURE
FOR DETERMINING SEGREGATION IN HOT BITUMINOUS PAVEMENT
1. Place the nuclear density gauge on the visually suspect area of the compacted surface. Move the handle down to the backscatter position and take a one minute count. Determine the density in PCF and record this as reading A.
2 . Place the nuclear density gauge on an adjacent area of the compacted surface. Move the handle down to the backscatter position and take a one minute count. Determine the density i n PCF and record this as reading B.
3 . If B-A is greater than 5 PCF, the material in the suspect area is segregated and should be removed.
Note: This procedure is intended to establish a method to identify segregated areas. After confidence is reached, segregation can be determined by visual inspection alone.
F-1
APPENDIX G
AGGREGATE MOISTURE CONTENT WITH LIME
AGGREGATE MOISTURE CONTENT WITH LIME
DRAFT
REVISION OP SECTION 401 PLANT HIXED PAVEMENTS-GENERAL
December 6, 1991
Section 401 of the standard specifications is hereby revised for this project as follows:
Subsection 401.14 (b) shall include the following:
Moisture content of the wet aggregate will be determined by the Division by drying to a constant weight at 230'F ± 9. Minimum sampling frequency will be 1/1000 tons or fraction thereof of mix produced. If moisture contents do not conform to specifications, payment for Hot Bituminous Pavement shall be reduced in accordance with 105.03 with an F factor of 20.
ALTERNATryE Below is an alternative specification using total moisture in place of moisture above . SSD. Since SSD for typical aggregates average 1.5% the 4.5% required below is equivalent to 3% above SSD.
REVISION OP SECTION 401 PLANT HIXED PAVEMENTS-GENERAL
December 6, 1991
Section 401 of the standard specifications is hereby revised for this project as follows:
Omit sUbsection 401.14 (b) and replace with the following.
(b) Dry Lime Added to Wet Aggregate. The dry hydrated lime shall be added to wet aggregate (a minimum of 4.5% total moisture) and then thoroughly mixed in a an approved pugmill. Moisture content of the wet aggregate will be determined by the Division by drying to a constant weight at 230"F ± 9. Minimum sampling frequency will be 1/1000 tons or fraction thereof of mix produced. If moisture contents do not conform to specifications, payment for Hot Bituminous Pavement shall be reduced in accordance with 105.03 with an F factor of 20.
G-l
APPENDIX H
COLORADO FLEXIBLE PAVEMENT OVERSIGHT GROUP TASK FORCE MEMBERS
Category: Issues:
Category: Issues:
Colorado Flexible Pavement Oversight Group Task Force Members
Pavement Management - Historic Data Base - Project Selection - Joint Review Committee - Economic Analysis - Inventory Element - Monitoring Element - Other
Pavement Design and Rehabilitation - Rehabilitation Strategies - Embankment & Drainage Requirements - Maintenance Strategies - Other
Steve Horton, Chair Dave Fraser Bill Keller Jim DeBerry Doyt Y. Bolling A.G. Peterson Robert Rask Bil.l Lauer Ira Paulin Paul Rippy Gene Arnold
Robert Rask, Chair Ken Mauro Dave Fraser Skip Bettis Paul Rippy Dick Klinker Steve Horton Carl Stuka Rose McDonald Tom "Claret Doyt Bolling Bob Bisgard Ira Paulin
Category: Issues:
Category: Issues:
category: Issues:
Material Selection Specifications - Mix Design Criteria - Binder Specifications - Aggregate Contractor Sources - Lime Antistrip - Other
Mix Design Systems - Texas Gyratory - SHRP AAMAS (Superphalt) - European AAMAS - Other
Training - Mix Design - Laboratory Testing - Pavement Management - NICET/Bitum. Technical Cert. - Aggregate Technical Cert. - Plant Operation - Construction Procedures
Inspection - Pavement Maintenance and
Rehabilitation - Training Opportunities for
Development - Other
H-2
Dick Hines, Chair Vuk Aguirre Paul Rippy Tony Collins Mark Swanlund Carl Stuka Charlie Atherton Ken Mauro Jim DeBerry Robert Rask Larry Johnson Bob Bisgard Skip Bettis Sid Motchan
Tim Aschenbrener, Chair Jim Fife Harold Elam Tony Collins Ken Mauro Tom Claret A.G. Peterson L. Scott Hendricks Victoria Peters Bob Welch
Mark Swanlund, Chair Jim Fife Harold Elam Tony Collins Victoria Peters Carl Stuka Ken Wood Tony Ursini Bud Brakey
Category: New Materials Technologies Issues: - Modifiers
- Fabrics - Drainable Bases - Stone Mastic Asphalt - Other
Category: Constructability Factor Issues: - Designing for Constructability
- Pre-bid/Pre-Construction /Pre-paving Conferencing
Category: Issues:
- Field Constructability Assessment (CMO's)
- Workmanship - Aggregate Stockpiles - plant Operations - 'transport - Laydown - Compaction - Specification Review - project Closeout Review - Project site Logistic/Traffic
Constraints - Automated Equipment Controls - Other
QA/QC - Test Methods, Accuracy and
Precision - Testing Frequency - Independent Assurance - Sampling Techniques
(size, location, safety) - Quality Control and Producer
Capability - Plant Certification and Calibration - Acceptance Procedures Plan - Identification and Evaluation of
Well Performing Projects - Performance Monitoring
(as constructed conditions) - Inspection procedures - Other
H-3
Ken Wood, Chair Jim Fife Tony Collins Owen Hill Denis Donnelly Jim DeBerry Stan Peters Buck Richardson Sid Motchan
Tony Ursini, Chair Bill Lauer Harold Elam Paul Rippy Carl Stuka Jeff Killer Skip Bettis Mike Mikkelson John Unbewust
Denis Donnelly, John Unbewust Dick Klinker Bud Brakey Carl Stuka John Unbewust Ken Mauro Ira Paulin
Chair
Category: Issues:
Awards Pavement Quality Workmanship
Award Incentives Publicity Other
H-4
Rick DeLaCastro, Chair Mike Mikkelson Dick Klinker Curt Marrel Charlie Atherton Ken Mauro Doyt Bolling Jim DeBerry George Osborne Bob Clevenger Bill Keller
APPENDIX I
GYRATORY COMPACTOR TEST PROCEDURE
. ..
DEPARTMENT OF HIGHWAYS
4201 East Arkansas Ave. Denv.r, Colorado 80222 •
DATE: November 26, 1991
TO: District Materials
f};j{~ FROM: Dick Hines
SUBJECT: Modification of the
MEMORANDUM
, .
Engineers
Gyratory compaction for Hveem
The compaction of Hveem specimens on the gyratory compactor has been modified by reducing the specimen height to 2". The revised procedure is attached. This revised procedure will now be used for all Hveem compactions.
This modification will result in higher asphalt contents at optimum. The attached correlation study shows how compaction method affected the optimum AC for 10 mixes.
This new method will result in mixes that are less difficult to compact and less susceptable to moisture damage.
DH/hs cc Clevenger/Shaffer
Donnelly Unbewust Horton Bill Grey, Design Rick DeLaCastro, CAPA Jay Lower, CCA
1-1
,
,
Colorado Procedure L-5105
Revised Nov 1991
Method at Test For .
RESISTANCE TO DEFORMA110N OF BmJMINOUS MIXTURES BY MEANS OF HVEEM STABILOMETER
Test specimens will be prepared In accordance wtth ASTM D 4013 (modified). Bulk specific gravity is then determined in accordance wtth AASHTO T 166. Hveem Stability is then determined in accordance wtth AASHTO T 246 (modnied).
SaEcnON OF BmJMEN CONTENT FOR SPECIMENS
1.1 Determine an estimated asphalt cement content tor the specimen. Normally, tests will be conducted using tour asphalt cement contents, wtth an incremental change of 0.5 %.
PREPARA110N OF SPECIMENS
2. 1 Specimens will be mixed and compacted in accordance with ASTM D 4013 as modified below. Specimen height shall be from 2.00 to 2. 19 inches. Total loads on the 4' diameter specimen tor pregyration stress, end point stress, and consoridation stress are 400 lb., 1200 lb. and 20,000 lb. respectively. This corresponds to gauge pressures of 50 psi, 150 psi, and 2500 psi for a ram diameter of 3.19 in.
2.2 Mixing and compaction shaJI be at the temperatures shown in the following table for normal asphalt cement and asphalt cement that has been modified by addition of rubber or polymer. The tolerances for each shaJI be + 5°F. -
1-2
Normal Modified
Mixing 275°F 325°F
Compact 250°F 300°F
. 2.3 Aggregate and asphalt cement shall be heated a minimum at 2 hours before mixing. The mix shall then be reheated for a minimum of 30 minutes before compacting. Mixed production samples shall be heated for a mininium of 2 hours before compaction. If a production sample is received at a temperature of 200°F or higher, the heating time can be reduced to 30 minutes.
Note 1: Fo~ a· smooth top and bottom on the specimen place 30 to 50 g. of fine material on the top and bottom when loading for compaction.
Note 2: Apply the pump strokes smoothly when Checki~g '!Je end ~int stress and applying the consolidation Oevellng) load. The leveling load strokes should be applied at the rate of one stroke per second, after the change to the high range gauge.
BULK SPECIAC GRAVITY DETERMlNA110N
3. 1 Determine bulk specific gravity of specimen in accordance with AASHTO T 166. This is used with the maximum specific gravity (AASHTO T 209) to compute the air voids as follows:
Percent air voidS a
( 1 -bulk sp. gr. ----)xl00 Max. sp. gr.
· '
HVEEM STABIUTY DETERMlNA110N.
4.1 Hveem Stability shaD be determined in accordance with AASHTO T 246 sections 4, 5, and 6 with the foDowing mod'lficallons. The specimen is to be transferred from the oven to the stabilometer, not pushed from the mOld. The stabRometer gauge reading Is recorded only at a vertical load of 5000 I~f.
HEAl1NG FOR HVEEM STABIUTY
5.1 Bring the specimen to a temperature of 1400 ± 50 F by preheating at that temperature for a minimum of 1 1/2 hours.
5.2 The stabilometer base and follower wUl be preheated at 1400 ± SO F for a minimum of 1 hour.
smCTION OF OPTlMUM ASPHALT CEMENT CONTENT
6.1 Optimum asphalt cement content Is chosen where 'all the design criteria are satisfied. Design criteria are specified in the plans (voids, stability, VMA, and asphalt cement film thickness). In addition, the mix should conform to a dust to asphalt ratio criteria of 0.6 to 1.2.
6.2 Optimum shaD be established at the center of the void range if an the abOVe criteria are satisfied at the corresponding asphalt cement content It the design criteria are not satisfied at the center of the void range, then optimum shall be established at the closest asphalt cement content which satisfies all design criteria If there is no asphalt cement content at which all specified design criteria are satISfied, then the mix is not acceptable.
6.3 The moisture susceptibRity test shan be conducted at the final optimum asphalt cement content It the moisture susceptibility test meets the specified design criteria, the mix is acceptable.
I-3
'. , - .
,',